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Chapter 22: Current Electricity Click the mouse or press the spacebar to continue.

In this chapter you will:
Explain energy transfer in circuits. Solve problems involving current, potential difference, and resistance. Diagram simple electric circuits. Chapter Introduction

Chapter 22: Current Electricity
Section 22.1: Current and Circuits Section 22.2: Using Electric Energy Chapter Menu

In this section you will:
Describe conditions that create current in an electric circuit. Explain Ohm’s law. Design closed circuits. Differentiate between power and energy in an electric circuit. Section

Producing Electric Current
Flowing water at the top of a waterfall has both potential and kinetic energy. However, the large amount of natural potential and kinetic energy available from resources such as Niagara Falls are of little use to people or manufacturers who are 100 km away, unless that energy can be transported efficiently. Electric energy provides the means to transfer large quantities of energy over great distances with little loss. Section

This transfer is usually done at high potential differences through power lines. Once this energy reaches the consumer, it can easily be converted into another form or combination of forms, including sound, light, thermal energy, and motion. Because electric energy can so easily be changed into other forms, it has become indispensable in our daily lives. Section

When two conducting spheres touch, charges flow from the sphere at a higher potential to the one at a lower potential. The flow continues until there is no potential difference between the two spheres. A flow of charged particles is an electric current. Section

In the figure, two conductors, A and B, are connected by a wire conductor, C. Charges flow from the higher potential difference of B to A through C. This flow of positive charge is called conventional current. The flow stops when the potential difference between A, B, and C is zero. Section

You could maintain the electric potential difference between B and A by pumping charged particles from A back to B, as illustrated in the figure. Since the pump increases the electric potential energy of the charges, it requires an external energy source to run. This energy could come from a variety of sources. Section

One familiar source, a voltaic or galvanic cell (a common dry cell), converts chemical energy to electric energy. A battery is made up of several galvanic cells connected together. A second source of electric energy— a photovoltaic cell, or solar cell—changes light energy into electric energy. Section

Electric Circuits The charges in the figure move around a closed loop, cycling from pump B, through C to A, and back to the pump. Any closed loop or conducting path allowing electric charges to flow is called an electric circuit. Section

Electric Circuits A circuit includes a charge pump, which increases the potential energy of the charges flowing from A to B, and a device that reduces the potential energy of the charges flowing from B to A. Section

Electric Circuits The potential energy lost by the charges, qV, moving through the device is usually converted into some other form of energy. For example, electric energy is converted to kinetic energy by a motor, to light energy by a lamp, and to thermal energy by a heater. A charge pump creates the flow of charged particles that make up a current. Section

Click image to view the movie.
Electric Circuits Movie Like Animation of the waterwheel gnerator. Click image to view the movie. Section

Conservation of Charge
Charges cannot be created or destroyed, but they can be separated. Thus, the total amount of charge—the number of negative electrons and positive ions—in the circuit does not change. If one coulomb flows through the generator in 1 s, then one coulomb also will flow through the motor in 1 s. Thus, charge is a conserved quantity. Section

Conservation of Charge
Energy is also conserved. The change in electric energy, ΔE, equals qV. Because q is conserved, the net change in potential energy of the charges going completely around the circuit must be zero. The increase in potential difference produced by the generator equals the decrease in potential difference across the motor. Section

Rates of Charge Flow and Energy Transfer
Power, which is defined in watts, W, measures the rate at which energy is transferred. If a generator transfers 1 J of kinetic energy to electric energy each second, it is transferring energy at the rate of 1 J/s, or 1 W. The energy carried by an electric current depends on the charge transferred, q, and the potential difference across which it moves, V. Thus, E = qV. Section

The unit for the quantity of electric charge is the coulomb. The rate of flow of electric charge, q/t, called electric current, is measured in coulombs per second. Electric current is represented by I, so I = q/t. A flow of 1 C/s is called an ampere, A. Section

The energy carried by an electric current is related to the voltage, E = qV. Since current, I = q/t, is the rate of charge flow, the power, P = E/t, of an electric device can be determined by multiplying voltage and current. Section

To derive the familiar form of the equation for the power delivered to an electric device, you can use P = E/t and substitute E = qV and q = It Power P = IV Power is equal to the current times the potential difference. Section

Resistance and Ohm’s Law
Suppose two conductors have a potential difference between them. If they are connected with a copper rod, a large current is created. On the other hand, putting a glass rod between them creates almost no current. The property determining how much current will flow is called resistance. Section

The table lists some of the factors that impact resistance. Section

Resistance is measured by placing a potential difference across a conductor and dividing the voltage by the current. The resistance, R, is defined as the ratio of electric potential difference, V, to the current, I. Resistance Resistance is equal to voltage divided by current. Section

The resistance of the conductor, R, is measured in ohms. One ohm (1 Ω) is the resistance permitting an electric charge of 1 A to flow when a potential difference of 1 V is applied across the resistance. A simple circuit relating resistance, current, and voltage is shown in the figure. Section

A 12-V car battery is connected to one of the car’s 3-Ω brake lights. The circuit is completed by a connection to an ammeter, which is a device that measures current. The current carrying the energy to the lights will measure 4 A. Section

The unit for resistance is named for German scientist Georg Simon Ohm, who found that the ratio of potential difference to current is constant for a given conductor. The resistance for most conductors does not vary as the magnitude or direction of the potential applied to it changes. A device having constant resistance independent of the potential difference obeys Ohm’s law. Section

Most metallic conductors obey Ohm’s law, at least over a limited range of voltages. Many important devices, such as transistors and diodes in radios and pocket calculators, and lightbulbs do not obey Ohm’s law. Wires used to connect electric devices have low resistance. A 1-m length of a typical wire used in physics labs has a resistance of about 0.03 Ω. Section

Because wires have so little resistance, there is almost no potential drop across them. To produce greater potential drops, a large resistance concentrated into a small volume is necessary. A resistor is a device designed to have a specific resistance. Resistors may be made of graphite, semiconductors, or wires that are long and thin. Section

There are two ways to control the current in a circuit. Because I =V/R, I can be changed by varying V, R, or both. The figure A shows a simple circuit. When V is 6 V and R is 30 Ω, the current is 0.2 A. Section

How could the current be reduced to 0.1 A? According to Ohm’s law, the greater the voltage placed across a resistor, the larger the current passing through it. If the current through a resistor is cut in half, the potential difference also is cut in half. Section

In the first figure, the voltage applied across the resistor is reduced from 6 V to 3 V to reduce the current to 0.1 A. A second way to reduce the current to 0.1 A is to replace the 30-Ω resistor with a 60-Ω resistor, as shown in the second figure. Section

Resistors often are used to control the current in circuits or parts of circuits. Sometimes, a smooth, continuous variation of the current is desired. For example, the speed control on some electric motors allows continuous, rather than step-by- step, changes in the rotation of the motor. Section

To achieve this kind of control, a variable resistor, called a potentiometer, is used. A circuit containing a potentiometer is shown in the figure. Section

Some variable resistors consist of a coil of resistance wire and a sliding contact point. Moving the contact point to various positions along the coil varies the amount of wire in the circuit. As more wire is placed in the circuit, the resistance of the circuit increases; thus, the current changes in accordance with the equation I = V/R. Section

In this way, the speed of a motor can be adjusted from fast, with little wire in the circuit, to slow, with a lot of wire in the circuit. Other examples of using variable resistors to adjust the levels of electrical energy can be found on the front of a TV: the volume, brightness, contrast, tone, and hue controls are all variable resistors. Section

The Human Body The human body acts as a variable resistor.
When dry, skin’s resistance is high enough to keep currents that are produced by small and moderate voltages low. If skin becomes wet, however, its resistance is lower, and the electric current can rise to dangerous levels. A current as low as 1 mA can be felt as a mild shock, while currents of 15 mA can cause loss of muscle control, and currents of 100 mA can cause death. Section

Diagramming Circuits An electric circuit is drawn using standard symbols for the circuit elements. Section

Diagramming Circuits Such a diagram is called a circuit schematic. Some of the symbols used in circuit schematics are shown below. Section

Current Through a Resistor
A 30.0-V battery is connected to a 10.0-Ω resistor. What is the current in the circuit? Section

Step 1: Analyze and Sketch the Problem
Current Through a Resistor Step 1: Analyze and Sketch the Problem Section

Draw a circuit containing a battery, an ammeter, and a resistor. Section

Show the direction of the conventional current. Section

Identify the known and unknown variables. Known: V = 30.0 V R = 10 Ω Unknown: I = ? Section

Step 2: Solve for the Unknown
Current Through a Resistor Step 2: Solve for the Unknown Section

Use I = V/R to determine the current. Section

Substitute V = 30.0 V, R = 10.0 Ω Section

Step 3: Evaluate the Answer
Current Through a Resistor Step 3: Evaluate the Answer Section

Are the units correct? Current is measured in amperes. Is the magnitude realistic? There is a fairly large voltage and a small resistance, so a current of 3.00 A is reasonable. Section

The steps covered were: Step 1: Analyze and Sketch the Problem Draw a circuit containing a battery, an ammeter, and a resistor. Show the direction of the conventional current. Section

The steps covered were: Step 2: Solve for the Unknown Use I = V/R to determine the current. Step 3: Evaluate the Answer Section

Diagramming Circuits An artist’s drawing and a schematic of the same circuit are shown below. Section

Diagramming Circuits An ammeter measures current and a voltmeter measures potential differences. Each instrument has two terminals, usually labeled + and –. A voltmeter measures the potential difference across any component of a circuit. When connecting the voltmeter in a circuit, always connect the + terminal to the end of the circuit component that is closer to the positive terminal of the battery, and connect the – terminal to the other side of the component. Section

Diagramming Circuits When a voltmeter is connected across another component, it is called a parallel connection because the circuit component and the voltmeter are aligned parallel to each other in the circuit, as diagrammed in the figure. Section

Diagramming Circuits Any time the current has two or more paths to follow, the connection is labeled parallel. The potential difference across the voltmeter is equal to the potential difference across the circuit element. Always associate the words voltage across with a parallel connection. Section

Diagramming Circuits An ammeter measures the current through a circuit component. The same current going through the component must go through the ammeter, so there can be only one current path. A connection with only one current path is called a series connection. Section

Diagramming Circuits To add an ammeter to a circuit, the wire connected to the circuit component must be removed and connected to the ammeter instead. Then, another wire is connected from the second terminal of the ammeter to the circuit component. In a series connection, there can be only a single path through the connection. Always associate the words current through with a series connection. Section

Question 1 What is an electric current? Section

Answer 1 An electric current is a flow of charged particles. It is measured in C/s, which is called an ampere, A. Section

Question 2 In a simple circuit, a potential difference of 12 V is applied across a resistor of 60 Ω and a current of 0.2 A is passed through the circuit. Which of the following statements is true if you want to reduce the current to 0.1A? Section

Question 2 A. Replace the 60-Ω resistor with a 30-Ω resistor.
B. Replace the 60-Ω resistor with a 120-Ω resistor. C. Replace the potential difference of 12 V by a potential difference of 24 V. D. Replace the 60-Ω resistor with a 15-Ω resistor. Section

Answer 2 Reason: There are two ways to control the current in a circuit. Because I = V/R, I can be changed by varying V, R, or both. According to Ohm’s law, the greater the resistance of the resistor, the smaller the current passing through it. In order to halve the current passing through a resistor, the resistance of the resistor must be doubled. Hence, to reduce the current to 0.1 A, the 60- resistor must be replaced with a 120- resistor. Section

Question 3 A 12-V battery delivers a 2.0-A current to an electric motor. If the motor is switched on for 30 s, how much electric energy will the motor deliver? A. C. B. D. Section

Answer 3 Reason: Energy is equal to the product of power and time.
That is, E = Pt. Also, power is equal to the product of current and potential difference. That is, P = IV. Therefore, E = IVt = (2.0 A) (12 V) (30 s). Energy is measured is Joules (J). Section

Section 22.1

In this section you will:
Explain how electric energy is converted into thermal energy. Explore ways to deliver electric energy to consumers near and far. Define kilowatt-hour. Section

Energy Transfer in Electric Circuits
Energy that is supplied to a circuit can be used in many different ways. A motor converts electric energy to mechanical energy, and a lamp changes electric energy into light. Section

Energy Transfer in Electric Circuits
Unfortunately, not all of the energy delivered to a motor or a lamp ends up in a useful form. Some of the electric energy is converted into thermal energy. Some devices are designed to convert as much energy as possible into thermal energy. Section

Heating a Resistor Current moving through a resistor causes it to heat up because flowing electrons bump into the atoms in the resistor. These collisions increase the atoms’ kinetic energy and, thus, the temperature of the resistor. Section

Heating a Resistor A space heater, a hot plate, and the heating element in a hair dryer all are designed to convert electric energy into thermal energy. These and other household appliances act like resistors when they are in a circuit. Section

Heating a Resistor When charge, q, moves through a resistor, its potential difference is reduced by an amount, V. The energy change is represented by qV. In practical use, the rate at which energy is changed–the power, P = E/t–is more important. Current is the rate at which charge flows, I = q/t, and that power dissipated in a resistor is represented by P = IV. Section

Heating a Resistor For a resistor, V = IR.
Thus, if you know I and R, you can substitute V = IR into the equation for electric power to obtain the following. Power P = I2R Power is equal to current squared times resistance. Section

Heating a Resistor Thus, the power dissipated in a resistor is proportional to both the square of the current passing through it and to the resistance. If you know V and R, but not I, you can substitute I = V/R into P = IV to obtain the following equation. Power Power is equal to the voltage squared divided by the resistance. Section

Heating a Resistor The power is the rate at which energy is converted from one form to another. Energy is changed from electric to thermal energy, and the temperature of the resistor rises. If the resistor is an immersion heater or burner on an electric stovetop, for example, heat flows into cold water fast enough to bring the water to the boiling point in a few minutes. Section

Heating a Resistor If power continues to be dissipated at a uniform rate, then after time t, the energy converted to thermal energy will be E = Pt. Section

Heating a Resistor Because P = I2R and P = V2/R, the total energy to be converted to thermal energy can be written in the following ways. Thermal Energy E = I2Rt E = Pt E = Section

Heating a Resistor Thermal energy is equal to the power dissipated multiplied by the time. It is also equal to the current squared multiplied by resistance and time as well as the voltage squared divided by resistance multiplied by time. Section

Electric Heat A heater has a resistance of 10.0 Ω. It operates on V. a. What is the power dissipated by the heater? b. What thermal energy is supplied by the heater in 10.0 s? Section

Step 1: Analyze and Sketch the Problem
Electric Heat Step 1: Analyze and Sketch the Problem Section

Electric Heat Sketch the situation. Section

Electric Heat Label the known circuit components, which are a V potential difference source and a 10.0-Ω resistor. Section

Electric Heat Identify the known and unknown variables. Known:
V = V t = 10.0 s Unknown: P = ? E = ? Section

Step 2: Solve for the Unknown
Electric Heat Step 2: Solve for the Unknown Section

Electric Heat Because R and V are known, use P = V2/R.
Substitute V = V, R = 10.0 Ω. Section

Electric Heat Solve for the energy. E = Pt Section

Electric Heat Substitute P = 1.44 kW, t = 10.0 s.
E = (1.44 kW)(10.0 s) = 14.4 kJ Section

Step 3: Evaluate the Answer
Electric Heat Step 3: Evaluate the Answer Section

Electric Heat Are the units correct?
Power is measured in watts, and energy is measured in joules. Are the magnitudes realistic? For power, 102×102×10–1 = 103, so kilowatts is reasonable. For energy, 103×101 = 104, so an order of magnitude of 10,000 joules is reasonable. Section

Electric Heat The steps covered were:
Step 1: Analyze and Sketch the Problem Sketch the situation. Label the known circuit components, which are a V potential difference source and a 10.0-Ω resistor. Section

Electric Heat The steps covered were: Step 2: Solve for the Unknown
Because R and V are known, use P = V2/R. Solve for the energy. Step 3: Evaluate the Answer Section

Superconductors A superconductor is a material with zero resistance.
There is no restriction of current in superconductors, so there is no potential difference, V, across them. Because the power that is dissipated in a conductor is given by the product IV, a superconductor can conduct electricity without loss of energy. Section

Superconductors At present, almost all superconductors must be kept at temperatures below 100 K. The practical uses of superconductors include MRI magnets and in synchrotrons, which use huge amounts of current and can be kept at temperatures close to 0 K. Section

Transmission of Electric Energy
Hydroelectric facilities are capable of producing a great deal of energy. This hydroelectric energy often must be transmitted over long distances to reach homes and industries. How can the transmission occur with as little loss to thermal energy as possible? Section

Thermal energy is produced at a rate represented by P = I2R. Electrical engineers call this unwanted thermal energy the joule heating loss, or I2R loss. To reduce this loss, either the current, I, or the resistance, R, must be reduced. Section

All wires have some resistance, even though their resistance is small. The large wire used to carry electric current into a home has a resistance of 0.20 Ω for 1 km. Section

Suppose that a farmhouse was connected directly to a power plant 3.5 km away. The resistance in the wires needed to carry a current in a circuit to the home and back to the plant is represented by the following equation: R = 2(3.5 km)(0.20 Ω/km) = 1.4 Ω. Section

An electric stove might cause a 41-A current through the wires. The power dissipated in the wires is represented by the following relationships: P = I2R = (41 A)2 (1.4 Ω) = 2400 W. Section

All of this power is converted to thermal energy and, therefore, is wasted. This loss could be minimized by reducing the resistance. Cables of high conductivity and large diameter (and therefore low resistance) are available, but such cables are expensive and heavy. Because the loss of energy is also proportional to the square of the current in the conductors, it is even more important to keep the current in the transmission lines low. Section

How can the current in the transmission lines be kept low? The electric energy per second (power) transferred over a long-distance transmission line is determined by the relationship P = IV. The current is reduced without the power being reduced by an increase in the voltage. Some long-distance lines use voltages of more than 500,000 V. Section

The resulting lower current reduces the I2R loss in the lines by keeping the I2 factor low. Long-distance transmission lines always operate at voltages much higher than household voltages in order to reduce I2R loss. The output voltage from the generating plant is reduced upon arrival at electric substations to 2400 V, and again to 240 V or 120 V before being used in homes. Section

While electric companies often are called power companies, they actually provide energy rather than power. Power is the rate at which energy is delivered. When consumers pay their home electric bills, they pay for electric energy, not power. The amount of electric energy used by a device is its rate of energy consumption, in joules per second (W) times the number of seconds that the device is operated. Section

Joules per second times seconds, (J/s)s, equals the total amount of joules of energy. The joule, also defined as a watt-second, is a relatively small amount of energy, too small for commercial sales use. For this reason, electric companies measure energy sales in a unit of a large number of joules called a kilowatt-hour, kWh. A kilowatt-hour is equal to 1000 watts delivered continuously for 3600 s (1 h), or 3.6×106 J. Section

Question 1 The electric energy transferred to a light bulb is converted into light energy, but as the bulb glows, it becomes hot, which shows that some part of energy is converted into thermal energy. Why is this so? Section

Answer 1 When current is passed through a light bulb, it acts like a resistor. The current moving through a resistor causes it to heat up because the flowing electrons bump into the atoms in the resistor. These collisions increase the atoms kinetic energy and, thus, the temperature of the resistor (light bulb). This increase in temperature makes the resistor (light bulb) hot. Hence, some part of the electric energy supplied to a light bulb is converted into thermal energy. Section

Question 2 How can a superconductor conduct electricity without loss in energy? A. There is no potential difference across a superconductor. B. The potential difference across a superconductor is very high. C. The resistance of a superconductor is very high. D. Superconductors can only carry a negligible amount of current. Section

Answer 2 Reason: A superconductor is a material with zero resistance, so there is no potential difference, V, across one. Because the power dissipated in a conductor is given by the product IV, a superconductor can conduct electricity without loss of energy. Section

Question 3 Why do long distance transmission lines always operate at much higher voltages (almost 500,000 V) than the voltages provided by typical household outlets (120 V)? Section

Question 3 A. Because the resistance of long distance power lines is very high. B. Because there is a direct relationship between wire length and voltage. C. So that the current in the transmission line can be kept low. D. So that the transmission line is not damaged. Section

Answer 3 Reason: Thermal energy is produced at a rate represented by P = I2×R. In order that the transmission of electric energy occurs with as little loss to thermal energy as possible, both the current and the resistance must be kept as low as possible. Section

Answer 3 Reason: The resistance can be decreased by using cables of high conductivity and large diameter (and therefore low resistance). The current can be reduced without reducing the power transmitted by increasing the voltage. Hence, the current in long distance transmission lines is always kept low by operating them at very high voltages. Section

Section 22.2

A 30.0-V battery is connected to a 10.0-Ω resistor. What is the current in the circuit? Click the Back button to return to original slide. Q1

Electric Heat A heater has a resistance of 10.0 Ω. It operates on V. a. What is the power dissipated by the heater? b. What thermal energy is supplied by the heater in 10.0 s? Click the Back button to return to original slide. Q2

If the current through the motor in the figure on the next slide is 3.0 A and the potential difference is 120 V, the power in the motor is calculated using the expression P = (3.0 C/s)(120 J/C) = J/s, which is 360 W. Click the Back button to return to original slide. Ex1

Click the Back button to return to original slide. Ex1

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